Titanium alloy with improved properties

ABSTRACT

A titanium alloy having high strength, fine grain size, and low cost and a method of manufacturing the same is disclosed. In particular, the titanium alloy offers a room temperature longitudinal low cycle fatigue (LCF) maximum stress of at least about 950 MPa over about 20,000 cycles and a room temperature transverse low cycle fatigue (LCF) maximum stress of at least about 970 MPa over about 25,000 cycles. The titanium alloy is particularly useful for a multitude of applications including components of aircraft engines. The titanium alloy comprises, in weight percent, about 6.0 to about 6.7% aluminum, about 1.4 to about 2.0% vanadium, about 1.4 to about 2.0% molybdenum, about 0.20 to about 0.42% silicon, about 0.17 to about 0.23% oxygen, maximum about 0.24% iron, maximum about 0.08% carbon and balance titanium with incidental impurities.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No. 13/349,483, filed on Jan. 12, 2012, now U.S. Pat. No. 10,119,178 issued on Nov. 6, 2018. The disclosure of the above application is incorporated herein by reference.

FIELD

The present disclosure relates to titanium (Ti) alloys. In particular, alpha-beta Ti alloys having an improved combination of mechanical properties achieved with a relatively low-cost composition are described as well as methods of manufacturing the Ti alloys.

BACKGROUND

The statements in this section merely provide background information related to the present disclosure and may not constitute prior art.

Ti alloys have found widespread use in applications requiring high strength-to-weight ratios, good corrosion resistance and retention of these properties at elevated temperatures. Despite these advantages, the higher raw material and processing costs of Ti alloys compared to steel and other alloys have severely limited their use to applications where the need for improved efficiency and performance outweigh their comparatively higher cost. Some typical applications which have benefited from the incorporation of Ti alloys in various capacities include, but are not limited to, aeroengine discs, casings, fan and compressor blades; airframe components; orthopedic components; armor plate and various industrial/engineering applications.

A conventional Ti-base alloy which has been successfully used in a variety of applications is Ti-6Al-4V, which is also known as Ti 6-4. As the name suggests, this Ti alloy generally contains 6 wt. % aluminum (Al) and 4 wt. % vanadium (V). Ti 6-4 also typically includes up to 0.30 wt. % iron (Fe) and up to 0.30 wt. % oxygen (O). Ti 6-4 has become established as the “workhorse” titanium alloy where strength/weight ratio at moderate temperatures is a key parameter for material selection. Ti 6-4 has a balance of properties which is suitable for a wide variety of static and dynamic structural applications, it can be reliably processed to give consistent properties, and it is comparatively economical.

Recently, the design of new aircraft engines has been driven by airline demands for reduced atmospheric emissions and noise, reduced fuel costs, and reduced maintenance and spare part costs. Competition between engine builders has caused them to respond by designing engines with higher bypass ratios, higher pressures in the compressor, and higher temperatures in the turbine. These enhanced mechanical properties require an alloy that has a higher strength than Ti 6-4, but the same density and near equivalent ductility.

Other alloys, such as TIMETAL® 550 (Ti-4.0Al-4.0Mo-2.0Sn-0.5Si) and VT 8 (Ti-6.0Al-3.2Mo-0.4Fe-0.3Si—0.15O), gain approximately 100 MPa of strength compared to Ti 6-4 from the inclusion of silicon in the alloy. However, these alloys have a higher density and a higher production cost, compared to Ti 6-4, because they use molybdenum as the main beta stabilizing element, as opposed to vanadium. The cost premium arises not only from the greater cost of molybdenum relative to vanadium, but also because the use of Ti 6-4 turnings and machining chip as a raw material is precluded in those alloys.

Therefore, there is a need in the industry to provide a cost-effective alloy that has a higher strength, finer grain size, and a particularly improved Low Cycle Fatigue Life with a comparable density when compared to Ti 6-4.

SUMMARY

In one form of the present disclosure, a titanium alloy comprising, in weight %: aluminum from 6.0 to 6.7; vanadium from 1.4 to 2.0; molybdenum from 1.4 to 2.0; silicon from 0.20 to 0.42; oxygen from 0.17 to 0.23; iron up to 0.24; carbon up to 0.08; and balance titanium with incidental impurities is disclosed. The titanium alloy has a room temperature longitudinal low cycle fatigue (LCF) maximum stress of at least about 950 MPa over about 20,000 cycles. In the alternative, or in addition to, the titanium alloy has a room temperature transverse LCF maximum stress of at least about 970 MPa over about 25,000 cycles. In some aspects of the present disclosure, the titanium alloy comprises at least one of, in weight %, aluminum from about 6.3 to 6.7; vanadium from about 1.5 to about 1.9; molybdenum from about 1.5 to about 1.9; silicon from about 0.34 to about 0.38; oxygen from about 0.18 to about 0.21; iron from about 0.1 to about 0.2; and carbon from about 0.01 to about 0.05. In other aspects of the present disclosure, the titanium alloy comprises at least one of, in weight %, aluminum at about 6.5; vanadium at about 1.7; molybdenum at about 1.7; silicon at about 0.36; oxygen at about 0.2; iron at about 0.16; carbon at about 0.03. The maximum concentration of any one impurity element present in the titanium alloy is 0.1 wt. % and the combined concentration of all impurities is less than or equal to 0.4 wt. %. Also, the titanium alloy comprises a molybdenum equivalence (Mo_(eq)) of 2.6 to 4.0 and an aluminum equivalence (Al_(eq)) of 10.6 to 12.9 when the molybdenum equivalence is defined as: Mo_(eq)=Mo+0.67V+2.9Fe and the aluminum equivalence is defined as: Al_(eq)=Al+27O.

In some aspects of the present disclosure, the titanium alloy comprises at least one of: an ultimate tensile strength (UTS) greater than 950 MPa (137 ksi); a tensile yield strength of about 1,000 MPa (145 ksi); an elongation of at least about 10%; a failure mechanism that is not dominated by localized adiabatic shear; a V50 ballistic limit that is at least 60 feet per second (18 m/s) greater than a base V50 ballistic limit measured for a T-64 alloy when a 0.616 inch (1.56 cm) thick plate is tested against a 12.7 mm diameter steel fragment simulating projectile; and a V50 ballistic limit that is at least 80 feet per second (24 m/s) greater than a base V50 ballistic limit measured for a T-64 alloy when a 0.616 inch (1.56 cm) thick plate is tested against a 12.7 mm diameter steel fragment simulating projectile. Also, a tensile specimen of the titanium alloy may have a reduction of area (RA) of at least about 25% of an original cross-sectional area of the tensile specimen after fracture when evaluated using an ASTM E8 standard. In such aspects, no secondary cracking occurs following an impact of the titanium alloy by the 12.7 mm diameter steel fragment simulating projectile. Also, the UTS of the titanium alloy may be at least at least 1100 MPa (160 ksi).

In some aspects of the present disclosure, the density of the titanium alloy is between 4.4 g/cm³ (0.161 lb./in³) and 4.55 g/cm³ (0.164 lb./in³). Also, the titanium alloy has a beta transus temperature between 1010° C. (1850° F.) and 1040° C. (1904° F.), a microstructure with a primary alpha phase in a background of beta phase, and/or a primary alpha phase with an alpha grain size of less than or equal to 15 μm.

In another form of the present disclosure, a titanium alloy comprising, in weight %, aluminum from about 6.3 to 6.7; vanadium from about 1.5 to about 1.9; molybdenum from about 1.5 to about 1.9; silicon from about 0.34 to about 0.38; oxygen from about 0.18 to about 0.21; iron from about 0.1 to about 0.2; carbon from about 0.01 to about 0.05; and balance titanium with incidental impurities is provided. In some aspects of the present disclosure the alloy has a room temperature longitudinal low cycle fatigue (LCF) maximum stress of at least about 950 MPa over about 20,000 cycles and a room temperature transverse LCF maximum stress of at least about 970 MPa over about 25,000 cycles. Also, the alloy may have a composition, in weight %, of aluminum at about 6.5; vanadium at about 1.7; molybdenum at about 1.7; silicon at about 0.36; oxygen at about 0.2; iron at about 0.16; carbon at about 0.03; and balance titanium with incidental impurities.

In still another form of the present disclosure, a titanium alloy comprising, in weight %, aluminum from about 6.3 to 6.7; vanadium from about 1.5 to about 1.9; molybdenum from about 1.5 to about 1.9; silicon from about 0.34 to about 0.38; oxygen from about 0.18 to about 0.21; iron from about 0.1 to about 0.2; carbon from about 0.01 to about 0.05; and balance titanium with incidental impurities is provided. The alloy has a molybdenum equivalence (Mo_(eq)) of 2.6 to 4.0 when the molybdenum equivalence is defined as: Mo_(eq)=Mo+0.67V+2.9Fe, and an aluminum equivalence (Al_(eq)) of 10.6 to about 12.9 when the aluminum equivalence is defined as: Al_(eq)=Al+27O. Also, the alloy has a room temperature LCF maximum stress of at least about 950 MPa over about 20,000. In some aspects of the present disclosure, the alloy has a composition comprising, in weight %, of aluminum at about 6.5; vanadium at about 1.7; molybdenum at about 1.7; silicon at about 0.36; oxygen at about 0.2; iron at about 0.16; carbon at about 0.03; and balance titanium with incidental impurities.

Numerous forms of the present disclosure form a part, aviation component, or fan blade with the alloy.

The alloy disclosed in this specification provides a comparative alternative to conventional Ti 6-4 alloys while meeting or exceeding mechanical properties established by the aerospace industry for Ti 6-4.

Further areas of applicability will become apparent from the description provided herein. It should be understood that the description and specific examples are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.

DRAWINGS

In order that the disclosure may be well understood, there will now be described various forms thereof, given by way of example, reference being made to the accompanying drawings, in which:

FIG. 1 is a flowchart illustrating a method of producing the titanium (Ti) alloy in accordance with the teachings of the present disclosure.

FIG. 2A is a microphotograph of a Ti 6-4 alloy.

FIG. 2B is a microphotograph of a comparative alloy containing Ti-6Al-2.6V-1 Mo.

FIG. 2C is a microphotograph of a comparative alloy containing Ti-6Al-2.6V-1 Mo-0.5Si.

FIG. 2D is a microphotograph of a Ti alloy in accordance with the teachings of the present disclosure.

FIG. 3 is schematic illustrating the considerations affecting various properties of the alloy based on the alloy's composition.

FIG. 4 is a graph providing room temperature low cycle fatigue results using smooth test pieces of the alloy taken traverse to the final rolling direction of the plate compared to Ti 6-4.

FIG. 5 is a graph providing room temperature low cycle fatigue results using notched test pieces of the alloy taken traverse to the final rolling direction of the plate compared to Ti 6-4.

FIG. 6 is a graph providing room temperature low cycle fatigue results using smooth test pieces of the Ti alloy taken longitudinal to the final rolling direction of the plate compared to Ti 6-4.

FIG. 7 is a graph providing room temperature low cycle fatigue results using notched test pieces of the Ti alloy taken longitudinal to the final rolling direction of the plate compared to Ti 6-4.

FIG. 8 is a graph providing high strain rate results of the Ti alloy compared to Ti 6-4.

The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way.

DETAILED DESCRIPTION

The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses. It should be understood that throughout the drawings, corresponding reference numerals indicate like or corresponding parts and features.

Exemplary titanium (Ti) alloys having good mechanical properties which are formed using reasonably low cost materials are described. These Ti alloys are especially suited for use in a multitude of applications including aircraft components requiring higher strength and low cycle fatigue resistance when compared to Ti 6-4, such applications include, but are not limited to, blades, discs, casings, pylon structures or undercarriage. Additionally, the Ti alloys are suited for general engineering components using titanium alloys where higher strength to weight ratio would be advantageous.

The Ti alloy comprises, in weight percent, about 6.0 to about 6.7% aluminum, about 1.4 to about 2.0% vanadium, about 1.4 to about 2.0% molybdenum, about 0.20 to about 0.42% silicon, about 0.17 to about 0.23% oxygen, maximum about 0.24% iron, maximum about 0.08% carbon and balance titanium with incidental impurities. Preferably, the Ti alloy comprises, in weight percent, about 6.0 to about 6.7% aluminum, about 1.4 to about 2.0% vanadium, about 1.4 to about 2.0% molybdenum, about 0.20 to about 0.42% silicon, about 0.17 to about 0.23% oxygen, about 0.1 to about 0.24% iron, maximum about 0.08% carbon and balance titanium with incidental impurities. More preferably, the alloy comprises about 6.3 to about 6.7% aluminum, about 1.5 to about 1.9% vanadium, about 1.5 to about 1.9% molybdenum, about 0.33 to about 0.39% silicon, about 0.18 to about 0.21% oxygen, 0.1 to 0.2% iron, 0.01 to 0.05% carbon, and balance titanium with incidental impurities. Even more preferably, the Ti alloy comprises, in weight percent, about 6.5% aluminum, about 1.7% vanadium, about 1.7% molybdenum, about 0.36% silicon, about 0.2% oxygen, about 0.16% iron, about 0.03% carbon and balance titanium with incidental impurities.

Aluminum as an alloying element in titanium is an alpha stabilizer, which increases the temperature at which the alpha phase is stable. Aluminum can be present in the alloy in a weight percentage of about 6.0 to about 6.7%. In particular, the aluminum is present at about 6.0, about 6.1, about 6.2, about 6.3, about 6.4, about 6.5, about 6.6, or about 6.7 wt. %. Preferably, the aluminum is present in a weight percentage of about 6.4 to about 6.7%. Even more preferably, the aluminum is present at about 6.5 wt. %. If the aluminum concentration were to exceed the upper limits disclosed in this specification, the workability of the alloy significantly deteriorates and the ductility and toughness worsen. On the other hand, the inclusion of aluminum levels below the limits disclosed in this specification can produce an alloy in which sufficient strength cannot be obtained.

Vanadium as an alloying element in titanium is an isomorphous beta stabilizer which lowers the beta transformation temperature. Vanadium can be present in the Ti alloy in a weight percentage of about 1.4 to about 2.0%. In particular, the vanadium is present in about 1.4, about 1.5, about 1.6, about 1.7, about 1.8, about 1.9, or 2.0 wt. %. Preferably, the vanadium is present in a weight percentage of about 1.5 to about 1.9%. More preferably, the vanadium is present at about 1.7 wt. %. If the vanadium concentration were to exceed the upper limits disclosed in this specification, the beta-stabilizer content of the alloy will be too high resulting in an increase in density relative to Ti 6-4. Also, if the vanadium concentration were to increase relative to the molybdenum content, the primary alpha grain size of the alloy would tend to increase. On the other hand, the use of vanadium levels that are too low can result in a deterioration in the strength and ductility of the alloy as the alloy tends toward near-alpha, rather than a true alpha-beta alloy. FIG. 3 provides a schematic diagram of the considerations in optimizing the vanadium and molybdenum contents of the Ti alloy.

Molybdenum as an alloying element in titanium is an isomorphous beta stabilizer which lowers the beta transformation temperature. Using the appropriate amount of molybdenum to cause refinement of the primary alpha grain size can provide improved ductility and fatigue life compared to an alloy using only vanadium as the beta stabilizing element. Molybdenum can be present in the Ti alloy in a weight percentage of about 1.4 to about 2.0%. In particular, the molybdenum is present in about 1.4, about 1.5, about 1.6, about 1.7, about 1.8, about 1.9, or about 2.0 wt. %. Preferably, the molybdenum is present in a weight percentage of about 1.5 to about 1.9%. Even more preferably, molybdenum is present at about 1.7 wt. %. If the molybdenum concentration were to exceed the upper limits disclosed in this specification, there is a technical disadvantage of increased density relative to Ti 6-4, and there is an economical and industrial consequence because the preeminence of Ti 6-4 as an industrial titanium alloy results in most of the scrap available for incorporation into ingots having that composition. Since the total beta stabilizer content of the alloy is limited to control the density, the proportion of beta stabilizers added as molybdenum is limited in order to optimize the economics of manufacture. On the other hand, the use of molybdenum levels below the limits disclosed in this specification can result in a deterioration in the strength and ductility of the alloy as the alloy tends toward near-alpha, rather than a true alpha-beta alloy.

Silicon as an alloying element in titanium is a eutectoid beta stabilizer which lowers the beta transformation temperature. Silicon can increase the strength and lower the density of titanium alloys. Additionally, silicon addition provides the required tensile strength without a major loss of the ductility, particularly when the molybdenum and vanadium balance is optimized. Furthermore, the silicon provides elevated temperature tensile properties relative to Ti 6-4 and similar to TIMETAL® 550. Silicon can be present in the Ti alloy in a weight percentage of about 0.2 to 0.42%. In particular, the silicon is present in about 0.20, about 0.22, about 0.24, about 0.26, about 0.28, about 0.30, about 0.32, about 0.34, about 0.36, about 0.38, about 0.40, or about 0.42 wt. %. Preferably, the silicon is present in a weight percent of about 0.34 to 0.38%. More preferably, the silicon is present at about 0.36 wt. %. If the silicon concentration were to exceed the upper limits disclosed in this specification, ductility, and toughness of the alloy will be deteriorated. On the other hand, the use of silicon levels below the limits disclosed in this specification can produce an alloy which has inferior strength.

Iron as an alloying element in titanium is a eutectoid beta stabilizer which lowers the beta transformation temperature, and iron is a strengthening element in titanium at ambient temperatures. Iron can be present in the Ti alloy in a maximum weight percentage of 0.24%. In particular, the iron can be present in about 0.04, about 0.8, about 0.10, about 0.12, about 0.15, about 0.16, about 0.20, or about 0.24 wt. %. Preferably, the iron is present in a weight percentage of about 0.10 to about 0.20%. More preferably, iron is present at about 0.16 wt. %. If the iron concentration were to exceed the upper limits disclosed in this specification, there will potentially be a segregation problem with the alloy and ductility and formability will consequently be reduced. On the other hand, the use of iron levels below the limits disclosed in this specification can produce an alloy that fails to achieve the desired high strength, deep hardenability, and excellent ductility properties.

Oxygen as an alloying element in titanium is an alpha stabilizer, and oxygen is an effective strengthening element in titanium alloys at ambient temperatures. Oxygen can be present in the Ti alloy in a weight percentage of about 0.17 to about 0.23%. In particular, the oxygen is present at about 0.17, about 0.18, about 0.19, about 0.20, about 0.21, about 0.22, or about 0.23 wt. %. Preferably, the oxygen is present in a weight percent of about 0.19 to about 0.21%. More preferably, oxygen is present at about 0.20 wt. %. If the content of oxygen is too low, the strength can be too low and the cost of the Ti alloy can increase because scrap metal will not be suitable for use in the melting of the Ti alloy. On the other hand, if the oxygen content is too great, ductility, toughness and formability will be deteriorated.

Carbon as an alloying element in titanium is an alpha stabilizer, which increases the temperature at which the alpha phase is stable. Carbon can be present in the Ti alloy in a maximum weight percentage of about 0.08%. In particular, the carbon is present in about 0.01, about 0.02, about 0.03, about 0.04, about 0.05, about 0.06, about 0.07, or about 0.08 wt. %. Preferably, the carbon is present in a weight percent of about 0.01 to about 0.05%. More preferably, the carbon is present at about 0.03%. If the content of carbon is too low, the strength of the alloy can be too low and the cost of the Ti alloy can increase because scrap metal will not be suitable for use in the melting of the Ti alloy. On the other hand, if the carbon content is too great, then the ductility of the alloy will be reduced.

The alloys according to the present disclosure may consist essentially of the recited elements. It will be appreciated that in addition to those elements, which are mandatory, other non-specific elements may be present in the composition provided that the essential characteristics of the composition are not materially affected by their presence.

The Ti alloy can also include incidental impurities or other added elements, such as Co, Cr, Cu, Ga, Hf, Mn, N, Nb, Ni, S, Sn, P, Ta, and Zr at concentrations associated with impurity levels for each element. The maximum concentration of any one of the incidental impurity element or other added element is preferably about 0.1 wt. % and the combined concentration of all impurities and/or added elements preferably does not exceed a total of about 0.4 wt. %.

The density of the Ti alloy is calculated to be between about 0.1614 pounds per cubic inch (lb/in³) (4.47 g/cm³) and about 0.1639 lb/in³ (4.54 g/cm³) with a nominal density of about 0.1625 lb/in³ (4.50 g/cm³).

The Ti alloy has a beta transus of about 1850° F. (1010° C.) to about 1904° F. (1040° C.). The microstructure of the Ti alloy is indicative of an alloy processed below the beta transus. Generally, the microstructure of the Ti alloy has a primary alpha grain size at least as fine as, or finer than, Ti 6-4. In particular, the microstructures of the Ti alloy comprise primary alpha phase (white particles) in a background of transformed beta phase (dark background). It is preferable to obtain a microstructure in which the primary alpha grain size is as fine as possible, in order to maintain ductility as the strength of the alloy is increased by varying the composition. In some aspects of the present disclosure the primary alpha grain size may be less than about 15 μm.

The Ti alloy achieves excellent tensile properties. For example, when analyzed according to the ASTM E8 standard, the Ti alloy has a tensile yield strength (TYS) of at least about 145 ksi (1,000 MPa) and an ultimate tensile strength (UTS) of at least about 160 ksi (1,103 MPa) along both transverse and longitudinal directions. Additionally, the Ti alloy has an elongation of at least about 10%, and a reduction of area (RA) of at least about 25%.

The Ti titanium alloy has a molybdenum equivalence (Mo_(eq)) of 2.6 to 4.0, wherein the molybdenum equivalence is defined as: Mo_(eq)=Mo+0.67V+2.9Fe. In a particular application, the Mo_(eq) is 3.3.

The Ti titanium alloy aluminum equivalence (Al_(eq)) of 10.6 to about 12.9 wherein the aluminum equivalence is defined as: Al_(eq)=Al+27O. In a particular application, the Al_(eq) is 11.9.

Additionally, the Ti alloy maintains its strength advantage over Ti 6-4 at high strain rates while exhibiting equivalent ductility to Ti 6-4. Furthermore, ballistic testing has shown that the Ti alloy exhibits resistance to fragment simulating projectiles which is equal to or greater than that of Ti 6-4. In particular, the Ti alloy demonstrates a V50 of at least 60 fps in ballistic testing performed using 0.50 Cal. (12.7 mm) Fragment Simulating Projectiles (FSP). In particular applications, the Ti alloy demonstrates a V50 of at least 80 fps. Also the Ti alloy exhibits comparable fracture toughness when compared to Ti 6-4. As is the case for Ti 6-4, the Ti alloy is recognized to be capable of a range of property combinations, dependent on the processing and heat treatment of the material.

The Ti alloy can be manufactured into different products or components having a variety of uses. For example, the Ti alloy can be formed into aircraft components such as discs, casings, pylon structures or undercarriages as well as automotive parts. In a particular application, the Ti alloy is used as a fan blade.

Also disclosed is a method for manufacturing a Ti alloy having good mechanical properties. The method includes melting a combination of source materials in the appropriate proportions to produce the Ti alloy comprising, in weight about 6.0 to about 6.7% aluminum, about 1.4 to about 2.0% vanadium, about 1.4 to about 2.0% molybdenum, about 0.20 to about 0.42% silicon, about 0.17 to about 0.23% oxygen, about 0.1 to about 0.24% iron, maximum about 0.08% carbon and balance titanium with incidental impurities. Melting may be accomplished in, for example, a cold hearth furnace, optionally followed by remelting in a vacuum arc remelting (VAR) furnace. Alternatively, ingot production may be accomplished by multiple melting in VAR furnaces. The source materials may comprise a combination of recycled and virgin materials such as titanium scrap and titanium sponge in combination with small amounts of iron. Under most market conditions, the use of recycled materials offers significant cost savings. The recycled materials used may include, but are not limited to, Ti 6-4, Ti-10V-2Fe-3Al, other Ti—Al—V—Fe alloys, and CP titanium. Recycled materials may be in the form of machining chip (turnings), solid pieces, or remelted electrodes. The virgin materials used may include, but are not limited to, titanium sponge, aluminum-vanadium; aluminum-molybdenum; and titanium-silicon master alloys, iron powder, silicon granules, or aluminum shot. Since the use of Ti—Al—V alloy recycled materials allow reduced or no aluminum-vanadium master alloy to be used, significant cost savings can be attained. This does not, however, preclude the use and addition of virgin raw materials comprising titanium sponge and alloying elements rather than recycled materials if so desired.

The manufacturing method can also include melting ingots of the alloy and forging the Ti alloy in a sequence above and below the beta transformation temperature followed by forging and/or rolling below the beta transformation temperature. In a particular application, the method of manufacturing the Ti alloy is used to produce components for aviation systems, and even more specifically, to produce plates used in the manufacture of fan blades.

A flowchart which shows an exemplary method of manufacturing the Ti alloys is provided in FIG. 1. Initially, the desired quantity of raw materials having the appropriate concentrations and proportions are prepared in step 100. The raw materials can comprise recycled materials although they may be combined with virgin raw materials of the appropriate composition in any combination.

After preparation, the raw materials are melted and cast to produce an ingot in step 110. Melting may be accomplished by, for example, VAR, plasma arc melting, electron beam melting, consumable electrode skull melting or combinations thereof. In a particular application, double melt ingots are prepared by VAR and are cast directly into a crucible having a cylindrical shape.

In step 120, the ingot is subjected to initial forging or rolling. The initial forging or rolling is performed above the beta transformation temperature. If rolling is performed at this step, then the rolling is performed in the longitudinal direction. In a particular application the ingot of the titanium alloy is heated to a temperature between about 40 and about 200 degrees Centigrade above the beta transus temperature and forged to break down the cast structure of the ingot and then cooled. Preferably, the ingot of the titanium alloy is heated to a temperature between about 90 to about 115 degrees Centigrade above the beta transus. Even more preferably, the ingot is heated to about 90 degrees above the beta transus.

In step 130, which is optional, the ingot is reheated below the beta transformation temperature and forged to deform the transformed structure. In a particular application, the ingot is reheated to a temperature between about 30 and about 100 degrees Centigrade below the beta transus. Preferably, the ingot is reheated to a temperature between about 40 to about 60 degrees Centigrade below the beta transus. More preferably, the ingot is reheated to a temperature about 50 degrees Centigrade below the beta transus.

Next, in step 140, which is optional, the ingot is reheated to a temperature above the beta transus temperature to allow recrystallization of the beta phase, then forged to a strain of at least 10 percent and water quenched. In a particular application, the ingot is reheated to a temperature between about 30 and about 150 degrees Centigrade above the beta transus temperature. Preferably, the ingot is reheated to a temperature between about 40 and about 60 degrees Centigrade above the beta transus temperature. Even more preferably, the ingot is reheated to a temperature about 45 degrees Centigrade above the beta transus temperature.

In step 150 the ingot is subject to further forging and/or rolling to produce a plate, bar, or billet. The wrought ingot produced by step 120, or by optional steps 130 or 140, if performed, is reheated to a temperature between about 30 and about 100 degrees Centigrade below the beta transus and rolled to plate, bar, or billet of the desired dimensions, with the metal being reheated as necessary to allow the desired dimensions and microstructure to be achieved. In a particular application, the ingot is reheated to a temperature between about 30 and about 100 degrees Centigrade below the beta transus temperature. Preferably, the ingot is reheated to a temperature between about 40 and about 60 degrees Centigrade below the beta transus temperature. More preferably, the ingot is reheated to a temperature about 50 degrees Centigrade below the beta transus temperature.

Rolling of plate is typically (but optionally) accomplished in at least two stages, so that the material can be rotated through 90 degrees between stages, in order to promote the development of the microstructure of the plate. The final forging and rolling is performed below the beta transformation temperature with rolling being performed in the longitudinal and transverse directions, relative to the ingot axis.

The ingot is then annealed in step 160 which is preferably performed below the beta transformation temperature. The final rolled product may have a thickness which ranges from, but is not limited to, about 0.020 inches (0.508 mm) to about 4.0 inches (101.6 mm). In some variations, the annealing of plates may be accomplished with the plate constrained to ensure that the plate complies to a required geometry after cooling. In another application, plates may be heated to the annealing temperature and then leveled before annealing.

In some applications, rolling to gages below about 0.4 inches (10.16 mm) may be accomplished by hot rolling to produce a coil or strip product. In yet another application, rolling to thin gage sheet products may be accomplished by hot rolling of sheets as single sheets or as multiple sheets encased in steel packs.

Additional details on the exemplary titanium alloys and methods for their manufacture are described in the Examples which follow.

EXEMPLARY EXAMPLES

The examples provided in this section serve to illustrate the processing steps used, resulting composition and subsequent properties of Ti alloys prepared according to the teachings of the present disclosure. The Ti alloys and their associated methods of manufacture which are described below are provided as examples and are not intended to be limiting.

Example 1 Elemental Effects on a Ti 6-4 Base

Several Ti alloys having compositions outside the elemental ranges disclosed in this specification were initially prepared to serve as comparative examples. In evaluating the effectiveness of the elements contained in the proposed alloy, two series of 200 g buttons were melted and then (β then α/β) rolled to 13 mm square bars. The results are summarized in Table 1 below.

TABLE 1 Composition of Ti alloy (wt %) Second Heat 0.2% PS UTS % El % Alloy Al V Mo Si O Fe Treatment Step (MPa) (MPa) (5.65√So) RA A 6.5 4.2 — — 0.185 0.17 700 C./2 hr AC 890 989 17.5 42 (Ti64) B 6.5 2.6 1 — 0.195 0.17 700 C./2 hr AC 904 1002 17 42 C 6.5 2.6 1 0.5 0.21 0.17 400 C./24 hr AC 1028 1172 16.5 37 D 6.5 1.5 1 — 0.2 0.17 700 C./2 hr AC 877 994 18 38 E 6.5 1.5 1.5 — 0.2 0.17 700 C./2 hr AC 899 1009 19 44 Note: Tensile properties were evaluated using ASTM E8 standard. AC = Air Cooled; PS = Proof Stress; Initial Heat Treatment Step = 960° C./30 mins/AC.

Table 1 provides the tensile test results from five alloys including Ti 6-4. Table 1 demonstrates that comparable tensile test results were obtained when vanadium was substituted with molybdenum. Specifically, when the proportions of molybdenum and vanadium were varied between 1% to 2.6%, only minor changes in tensile strength compared to Ti 6-4 were observed (compare Alloys A, B, D, and E).

Table 1 also shows that the inclusion of 0.5% silicon resulted in a significant strength increase compared to an alloy without this element (compare Alloy C with Alloy B). Alloys A, B, D, and E were given a 2 stage heat treatment typically applied to Ti 6-4. Alloy C was heat treated under different conditions compared to the other alloys because of the inclusion of silicon. This heat treatment was selected because the prior art alloys that contain Si, such as TIMETAL® 550, suggested that the optimum properties of such alloys is typically attained when the final step of heat treatment is an aging process in the temperature range 400 to 500° C.

In titanium alloys, as for other metallic materials, the grain size has an influence on the mechanical properties of the material. Finer grain size is typically associated with higher strength, or with higher ductility at a given strength level. FIG. 2 shows the microstructure of experimental titanium alloys (see Table 1 for compositions) cast as 250 g ingots and converted by forging and rolling to 12 mm square bars. These microstructures comprise of primary alpha phase (white particles) in a background of transformed beta phase (dark background). FIG. 2A shows the microstructure of Alloy A (Ti 6-4) produced by this method, as a benchmark. It is desirable to obtain a microstructure in which the primary alpha grain size is as fine as possible, in order to maintain ductility as the strength of the alloy is increased by varying the composition. FIGS. 2B to 2D show the microstructures of experimental alloys (Alloys B, C, and E) containing molybdenum, which caused the transformed beta phase to appear darker. It had been empirically observed that titanium alloys in which molybdenum is the main beta stabilizing element tend to have a finer beta grain size than those in which vanadium is the main beta stabilizer. FIG. 2 shows that Alloy E (FIG. 2D) exhibited a finer primary alpha phase than Alloy A (Ti 6-4) (FIG. 2A), while Alloys B and C (FIGS. 2B and 2C) had grain sizes similar to that of Ti 6-4 (FIG. 2A). FIG. 2 demonstrates that in alloys containing both vanadium and molybdenum, the proportion of molybdenum present must be equal to or greater than the proportion of vanadium in order to obtain the desirable finer grain size.

Table 2 provides an additional set of eight buttons (nominal compositions) along with their tensile test results.

TABLE 2 Button Compositions and Tensile Test Results Composition of Ti alloy (wt %) β Transus E 0.2% PS UTS % El % Alloy Al V Mo Si O Fe (° C.) (GPa) (MPa) (MPa) (5.65√So) RA F 6.5 4.2 — — 0.2 0.17  995/1000 112 898 1048 16.5 37 (Ti64) G 6.5 4.2 — 0.5 0.2 0.17 1000/1005 112 1024 1165 14.5 35 H 6.5 — 3.2 0.35 0.2 0.17 1025/1030 114 1014 1188 14.5 38 I 6.5 2 2 0.5 0.2 0.17 1005/1010 112 1049 1218 13.5 40 J 6.5 2 2 0.35 0.2 0.17 1005/1010 113 1012 1187 15 40 K 6.5 1.5 1.5 0.5 0.2 0.17 1020/1025 114 996 1159 14.5 31 L 6.5 1.5 1.5 0.35 0.2 0.17 1020/1025 115 951 1125 15 37 M 6.5 2 2 0.5 0.15 0.17  995/1000 115 1016 1187 13.5 42 Note: All samples were solution heat treated at beta transformation temperature minus 40° C. for 1 hr and air cooled, then aged at 400° C. for 24 hrs and air cooled.

The results reported in Table 2 demonstrate the strengthening effect of including silicon m alloy compositions. For example, adding silicon to a Ti 6-4 base resulted in a substantial increase in tensile strength (compare Alloy F with Alloy G). Table 2 also shows that for any given base composition, the inclusion of 0.5% Si compared to 0.35% Si resulted in a higher strength (compare H, J, and L with I, K, and M, respectively).

Table 2 also shows the effects of varying the amount of molybdenum and vanadium in the alloys. Alloys that contained 2% Mo and 2% V had a higher strength and ductility compared to alloys that contained 1.5% Mo and 1.5% V (compare I and J with Land M, respectively).

Additionally, decreasing the oxygen content resulted in a lower strength for a given base composition (compare M with I). Furthermore, Table 2 shows that the elastic modulus varies little over the range of compositions analyzed.

FIG. 3 shows schematically the considerations affecting the molybdenum and vanadium balance selection. Using sufficient molybdenum to cause refinement of the primary alpha grain size is important in that it promotes superior fatigue performance relative to Ti 6-4 (similar to TIMETAL® 550). However, using an increased proportion of molybdenum has an economic/industrial consequence, in that the pre-eminence of Ti 6-4 as an industrial titanium alloy results in most of the scrap available for incorporation into ingots having that composition. Availability of scrap for incorporation has a major effect on the economics of introducing a novel alloy to industrial production.

The experimental work provided evidence that the principles of alloy design in FIG. 3 are effective in practice. The silicon addition provided an increase in tensile strength without a major loss of ductility, particularly when the molybdenum/vanadium balance was optimized. The inclusion of silicon also provided significant elevated temperature tensile properties relative to Ti 6-4 (similar to TIMETAL® 550).

Example 2

Additional experiments were performed to evaluate the chemical composition, calculated parameters, tensile properties, and ballistic properties of the Ti alloy. In particular, six ingots were melted as 8 inch (203 mm) diameter double VAR containing the compositions shown in Table 3 below. The material was converted to 0.62 inch (15.7 mm) plate with final subtransus rolling of 40% reduction in thickness in each direction.

Using the average chemical analysis results for the Ti alloy (Ti 639; Heat V8116), the beta transus was calculated to be 1884° F. (1029° C.). This value was confirmed using metallographic observation after quenching from successively higher annealing temperatures.

Density

The density of an alloy is an important consideration where the alloy selection criterion is (strength/weight) or (strength/weight squared). For an alloy which is proposed to be a substitute for Ti 6-4, it is particularly useful for the density to be equal to that of Ti 6-4 since this would allow substitution without design change where higher material performance is required.

Density calculations for each of the tested alloys is reported in Table 3. Using the rule of mixtures, the density for V8116 (Ti-6.5Al-1.8V-1.7Mo-0.16Fe-0.3Si-0.2O-0.03C) was calculated as 0.1626 lbs in⁻³ (4.50 g cm⁻³). When calculated on the same basis, the density of Ti 6-4 was 0.1609 lbs in⁻³ (4.46 g cm⁻³). Therefore, the density of V8116 is greater than that of Ti 6-4 by a factor of only about 1.011.

Solution Treated plus Overaged (STOA) Condition

Prior to determining the tensile properties of each alloy, the plates were heat treated to the solution treated plus overaged (STOA) condition as follows: Anneal 1760° F. (960° C.), 20 minutes, air cool (AC) to room temperature, then age 1292° F. (700° C.) for 2 h, AC.

Tensile property results are provided in Table 4. The Ti 6-4 baseline (V8111) exhibited typical properties for this formulation and heat treatment condition. The specific UTS and specific TYS of the Ti alloy (V8116) were approximately 9% and 12% higher, respectively, than that of the similarly processed Ti 6-4.

Ballistic Properties

Lab-scale ingots of the comparative compositions identified in Table 3 were melted and converted to 0.62 in (15.7 mm) cross-rolled plate. Tensile and ballistic evaluations were performed in the solution treated plus overaged condition as follows: Anneal 1760° F. (960° C.), 20 minutes, air cool (AC) to room temperature, then age 1292° F. (700° C.) for 2 h, AC.

Ballistic property results are provided in Table 3. Ballistic testing was performed using 0.50 Cal. (12.7 mm) Fragment Simulating Projectiles (FSP). Three plates were tested: V8111 (Ti 6-4), V8113 (Ti-6.5Al-1.8V-1.4Mo-0.16Fe-0.5Si-0.2O-0.06C), and V8116 (Ti-6.5Al-1.8V-1.7Mo-0.16Fe-0.3Si-0.2O-0.03C).

The ballistic results for V8116 were favorable demonstrating a V50 at 81 feet per second (fps) above the base requirement; localized adiabatic shear was not a dominant failure mechanism; and no secondary cracking occurred. The last observation is especially important because it indicates that the 0.03 wt % C and 0.3 Si wt % did not have a deleterious effect on the impact resistance. The overall ballistic performance for V8116 for these particular test conditions was found to be similar to that of Ti 6-4 (V8111). Therefore, the benefit of the higher strength of the V8116 composition can be realized without suffering a decrease in impact resistance.

In contrast, heat V8113, which had tensile properties similar to V8116 but had higher Si (0.5 vs. 0.3 wt %) and higher C (0.06 vs. 0.03 wt %), had a low V50 value (92 fps below the base requirement) and exhibited severe cracking that resulted in the plate breaking in half during the testing. The cracking of V8113 occurred even with shots of relatively low sectional impact energies. Additionally, V8113 exhibited cracking both between shots and to the corner of the plate; this behavior was not observed for Ti 6-4 (V8111) or V8116.

The combination of high strength (167 ksi UTS and 157 ksi), high elongation (11%), and good ballistic and impact properties observed for V8116 (Ti-6.5Al-1.8V-1.7Mo-0.16Fe-0.3Si—0.2O-0.03C) was very favorable considering that it avoids large alloy additions which would tend to increase density and cost that are normally associated with this strength level in Ti alloy plate.

TABLE 3 Material Product Composition, wt % Base Heat Al C Cr Fe Mo N Ni O Si Sn V Zr Nb Ti Ti 639 V8112 6.4 0.014 0.001 0.16 1.7 0.004 0.221 0.448 1.8 89.2 Ti 639 V8113 6.4 0.057 0.001 0.16 1.4 0.004 0.209 0.467 1.8 89.5 Ti 639 V8116 6.5 0.034 0.001 0.16 1.7 0.004 0.213 0.292 1.8 89.3 Ti 639 FU83099 6.6 0.030 0.16 1.8 0.003 0.213 0.292 1.7 89.3 Ti64 V8111 6.3 0.026 0.001 0.16 0.0 0.005 0.200 0.023 4.1 89.2 Ti64 + C V8117 6.4 0.051 0.001 0.16 0.0 0.005 0.213 0.038 4.1 89.1 Ti64 + C V8118 6.4 0.053 0.001 0.16 0.0 0.005 0.212 0.067 4.1 89.0 Ti 639 spec min 6.0 0.010 0.001 0.10 1.4 0.005 0.170 0.200 1.4 90.7 Ti 639 spec max 6.7 0.080 0.001 0.24 2.0 0.005 0.230 0.420 2.0 88.3 Ti 639 lowest density 6.7 0.080 0.001 0.10 1.4 0.005 0.230 0.420 1.4 89.7 Ti 639 highest density 6.0 0.010 0.001 0.24 2.0 0.005 0.170 0.200 2.0 89.4 Ti 639 typical 6.5 0.030 0.001 0.17 1.7 0.005 0.200 0.360 1.7 89.3 Ti 64 UK blend 6.5 0.010 0.001 0.17 0.0 0.005 0.210 0.010 4.2 88.9 Calculated Parameters ¹ Material Density T_(β) β_(ISO) Base Heat g/cc lb/in³ ° F. Al_(eq) Mo_(eq) β_(ISO) β_(EUT) β_(EUT) Ti 639 V8112 4.50 0.1626 1855 12.4 3.4 2.9 0.4 6.5 Ti 639 V8113 4.48 0.1619 1905 12.1 3.1 2.6 0.5 5.7 Ti 639 V8116 4.51 0.1627 1888 12.2 3.4 2.9 0.4 6.5 Ti 639 FU83099 4.50 0.1626 1888 12.3 3.3 2.9 0.5 6.1 Ti64 V8111 4.45 0.1606 1861 11.7 3.2 2.7 0.5 6.0 Ti64 + C V8117 4.45 0.1606 1894 12.1 3.2 2.7 0.5 5.9 Ti64 + C V8118 4.45 0.1605 1896 12.1 3.2 2.7 0.5 6.0 Ti 639 spec min 4.49 0.1622 1843 10.6 2.6 2.3 0.3 8.1 Ti 639 spec max 4.52 0.1631 1927 12.9 4.0 3.3 0.7 4.8 Ti 639 lowest density 4.47 0.1614 1955 12.9 2.6 2.3 0.3 8.1 Ti 639 highest density 4.54 0.1639 1815 10.6 4.0 3.3 0.7 4.8 Ti 639 typical 4.50 0.1625 1871 11.9 3.3 2.8 0.5 5.8 Ti 64 UK blend 4.45 0.1606 1852 12.2 3.3 2.8 0.5 5.7 Tensile Properties, Plate² Ballistic Properties Mill Annealed STA (Air Cool) V50 Test vs. 12.7 mm FSP Material UTS TYS RA El E UTS TYS RA El E t Base Tested Δ Base Heat ksi ksi % % Msi ksi ksi % % Msi (in) (fps) (fps) (fps) Comment Ti 639 V8112 161 154 19 11 17.3 170 163 23 8 17.9 — — — — Good Strength, marginal ductility Ti 639 V8113 161 153 20 12 17.5 169 158 21 11 18.3 0.605 3064 2972 −92 Good strength, good ductility, low V50 and severe cracking Ti 639 V8116 161 154 25 14 17.5 167 157 27 11 18.0 0.616 3137 3218 +81 Good combination of strength, ductility, V50, and cracking resistance Ti 639 FU83099 162 151 29 15 — — — — Ti64 V8111 151 139 29 13 16.4 155 141 30 12 17.8 0.585 2935 2993 +58 Typical strength, elongation and V50 for Ti 6-4 Ti64 + C V8117 156 143 26 14 16.7 159 147 26 11 17.9 — — — — Insufficient increase in strength Ti64 + C V8118 156 144 31 15 16.6 159 148 27 11 17.9 — — — — Insufficient increase in strength ¹ Density estimated using rule of mixtures. T_(β) (beta transus) calculations based on binary equilibrium phase diagrams. Al_(eq) = Al + 27O Mo_(eq) = Mo + 0.67V + 2.9Fe ²Average of 2 L and 2 T specimens for 0.6 in Plate El = using (5.65√So)

Example 3 Characteristics of an Intermediate Product Used in the Production of Hollow Titanium Alloy Fan Blades

In order to verify the properties of the Ti alloy (designated Ti 639) on an industrial scale, a 30 inch (760 mm) diameter ingot, nominal weight 3.4 MT, designated FU83099, was manufactured by double VAR melting. This ingot was then converted to plate in accordance with the processing principles laid out in FIG. 1, applying industrial practices used for commercial production of Ti 6-4 Fan Blade Plate. Part of the heat (FU83099B) was processed using the cross-rolling process, while another section of the heat (FU83099) was rolled along a single axis.

Room temperature tensile tests were also performed in order to further evaluate the characteristics of Ti 6-4 fan blade plate compared to the Ti alloy plate according to ASTM E8. Chemical compositions of the plates are shown in Table 4 along with the RT tensile test results.

The results from Table 4 further demonstrate that the Ti alloy is stronger than Ti 6-4. Comparison of the results from FU83099A and B demonstrates the greater anisotropy of properties in the material when the rolling is executed along a single axis, compared to cross rolling.

Samples taken from FU83099B were heat treated according to a schedule designed to simulate the manufacture of hollow titanium fan blades, and then subjected to a range of mechanical tests. FIGS. 4 to 8 show comparisons between Ti 6-4 and the Ti alloy (FU83099B), shown as Ti 639, in Low Cycle Fatigue testing, which infers the durability of the alloy in component service. FIGS. 4 and 6 show results from test pieces taken transverse and longitudinal respectively to the final rolling direction of the plate. FIGS. 4 and 6 provide the results from testing of ‘smooth’ test pieces, and clearly show the superiority of the Ti alloy compared to Ti 6-4. FIG. 4 shows results for “Ti 639” and “Ti 639 aged.” The “Ti 639 aged” samples received a heat treatment sequence in which the last step was in the aging range, at 500° C., but the “Ti 639” samples received a heat treatment sequence in which the last step was at 700° C., typical of annealing conditions. The results show that the good performance of the Ti alloy is achieved in both cases. The results show significant improvements in smooth low cycle fatigue performance of Ti 639 compared to Ti 6-4. In the transverse direction (FIG. 4) the fatigue life is increased from approximately 1×10⁴ cycles for Ti 6-4 to about 1×10⁵ cycles for Ti 639 at a maximum stress of about 890 MPa and the maximum stress for a life of about 1×10⁵ cycles is increased by approximately 100 MPa from 790 MPa for Ti 6-4 to approximately 890 MPa for Ti 639. In the longitudinal direction, the fatigue life is increased from less than 3×10⁴ cycles for Ti 6-4 to approximately 1×10⁵ cycles for Ti 639 at a maximum stress of 830 MPa and the maximum stress for a life of approximately 1×10⁵ cycles is increased from approximately 790 MPa for Ti 6-4 to about 830 MPa for Ti 639.

FIGS. 5 and 7 show the results of further Low Cycle Fatigue testing, from a more arduous test which uses a notched test piece. These results further confirm the superiority of the Ti alloy.

FIG. 8 provides a comparison between Ti 6-4 and the Ti alloy (FU83099B), shown as Ti 639, in high strain rate tensile testing. This data confirmed that the good combination of strength and ductility in the Ti alloy is superior to Ti 6-4 in the service condition relevant to hollow fan blades. This is relevant since such blades must be designed to withstand bird impacts in service, and the ability of the material to withstand such impacts influences the design, mass and efficiency of the component.

TABLE 4 Composition of Ti alloy (wt %) Second Heat 0.2% PS UTS % El Alloy Al V Mo Si O Fe C Treatment Step Dir. (MPa) (MPa) (4D) % RA R 6.33 1.63 1.66 0.31 0.207 0.17 0.026 700 C./2 hr AC L 1010.8 1080.4 15.6 34.5 (FU83099A2) L 1012.8 1083.2 15.2 35.5 T 1071.5 1154.2 15.2 23.3 T 1070.8 1152.1 14.5 23.4 S 6.34 1.63 1.7 0.31 0.203 0.17 0.024 700 C./2 hr AC L 1025.9 1110.1 15.9 31.5 (FU83099B) L 1025.9 1110.1 15.3 30.8 T 1034.9 1110.1 14.7 31 T 1033.5 1111.4 17.2 27 T 6.47 4.15 — 0.02 0.219 0.13 0.015 700 C./2 hr AC L 960.2 1048.6 16 29.8 (Ti 6-4) L 954 1047.5 16 33.7 T 952.4 1028.2 15.3 35.8 T 948.7 1027.6 14.3 33.6 Note: Initial heat treatment step = 960° C./30 mins/AC

In the interest of clarity, the following terms and acronyms are defined as provided below.

Tensile Yield Strength Engineering tensile stress at which the (TYS): material exhibits a specified limiting deviation (0.2%) from the proportionality of stress and strain. Ultimate Tensile Strength The maximum engineering tensile stress (UTS): which a material is capable of sustaining, calculated from the maximum load during a tension test carried out to rupture and the original cross-sectional area of the specimen. Modulus of Elasticity (E): Description of tensile elasticity, or the tendency of an object to deform along an axis when opposing forces are applied along that axis. Modulus of elasticity is defined as the ratio of tensile stress to tensile strain. Elongation (El): During a tension test, the increase in gage length (expressed as a percentage of the original gage length) after fracture. In this work, percentage of elongation was determined using two standard gage lengths. In the first method the gage length was determined according to the formula 5.65√So where So is the cross sectional area of the test piece. In the second method, the gage length was 4D where D is the diameter of the test piece. These differences, do not have a material effect on the determination of the percentage of elongation. Reduction in Area (RA): During a tension test, the decrease in cross-sectional area of a tensile specimen (expressed as a percentage of the original cross-sectional area) after fracture. Alpha (α) stabilizer: An element which, when dissolved in titanium, causes the beta transformation temperature to increase. Beta (β) stabilizer: An element which, when dissolved in titanium, causes the beta transformation temperature to decrease. Beta (β) transus: The lowest temperature at which a titanium alloy completes the allotropic transformation from an α + β to a β crystal structure. This is also known as the beta transformation temperature. Eutectoid compound: An intermetallic compound of titanium and a transition metal that forms by decomposition of a titanium-rich β phase. Isomorphous beta (β_(ISO)) A β stabilizing element that has similar stabilizer: phase relations to β titanium and does not form intermetallic compounds with titanium. Eutectoid beta (β_(EUT)) A β stabilizing element capable of forming stabilizer: intermetallic compounds with titanium. Proof Stress (PS) The stress that will cause a specified small, permanent extension of a tensile test piece. This value approximates to the yield stress in materials not exhibiting a definite yield point. The value for this set at 0.2% of the strain. Ingot The product of melting and casting and any intermediate product derived therefrom.

Unless otherwise expressly indicated herein, all numerical values indicating mechanical/thermal properties, compositional percentages, dimensions and/or tolerances, or other characteristics are to be understood as modified by the word “about” or “approximately” in describing the scope of the present disclosure. This modification is desired for various reasons including industrial practice, manufacturing technology, and testing capability.

The description of the disclosure is merely exemplary in nature and, thus, variations that do not depart from the substance of the disclosure are intended to be within the scope of the disclosure. Such variations are not to be regarded as a departure from the spirit and scope of the disclosure.

As used herein, the phrase at least one of A, B, and C should be construed to mean a logical (A OR B OR C), using a non-exclusive logical OR, and should not be construed to mean “at least one of A, at least one of B, and at least one of C.” 

What is claimed is:
 1. A titanium alloy comprising, in weight %: aluminum from 6.0 to 6.7; vanadium from 1.4 to 2.0; molybdenum from 1.4 to 2.0; silicon from 0.20 to 0.42; oxygen from 0.17 to 0.23; iron up to 0.24; carbon up to 0.08; and balance titanium with incidental impurities, wherein the alloy comprises at least one of: a room temperature longitudinal low cycle fatigue (LCF) maximum stress of at least about 950 MPa over about 20,000 cycles; and a room temperature transverse LCF maximum stress of at least about 970 MPa over about 25,000 cycles.
 2. The titanium alloy of claim 1, wherein the alloy comprises at least one of: aluminum from about 6.3 to 6.7; vanadium from about 1.5 to about 1.9; molybdenum from about 1.5 to about 1.9; silicon from about 0.34 to about 0.38; oxygen from about 0.18 to about 0.21; iron from about 0.1 to about 0.2; and carbon from about 0.01 to about 0.05.
 3. The titanium alloy of claim 1, wherein the alloy comprises: aluminum from about 6.3 to 6.7; vanadium from about 1.5 to about 1.9; molybdenum from about 1.5 to about 1.9; silicon from about 0.34 to about 0.38; oxygen from about 0.18 to about 0.21; iron from about 0.1 to about 0.2; carbon from about 0.01 to about 0.05; and balance titanium with incidental impurities.
 4. The titanium alloy of claim 1, wherein the alloy comprises: aluminum at about 6.5; vanadium at about 1.7; molybdenum at about 1.7; silicon at about 0.36; oxygen at about 0.2; iron at about 0.16; carbon at about 0.03; and the balance titanium with incidental impurities.
 5. The titanium alloy of claim 1, wherein the maximum concentration of any one impurity element present in the titanium alloy is 0.1 wt. % and the combined concentration of all impurities is less than or equal to 0.4 wt. %.
 6. The titanium alloy of claim 1, wherein a molybdenum equivalence (Mo_(eq)) of the alloy is 2.6 to 4.0 and the molybdenum equivalence is defined as: Mo_(eq)=Mo+0.67V+2.9Fe.
 7. The titanium alloy of claim 1, wherein an aluminum equivalence (Al_(eq)) of the alloy is 10.6 to 12.9 and the aluminum equivalence is defined as: Al_(eq)=Al+27O.
 8. The titanium alloy of claim 1, wherein: a molybdenum equivalence (Mo_(eq)) of the alloy is 2.6 to 4.0 and the molybdenum equivalence is defined as: Mo_(eq)=Mo+0.67V+2.9Fe; and an aluminum equivalence (Al_(eq)) of the alloy is 10.6 to about 12.9 and the aluminum equivalence is defined as: Al_(eq)=Al+27O.
 9. The titanium alloy of claim 1, wherein an ultimate tensile strength (UTS) of the alloy is greater than 950 MPa (137 ksi), a tensile yield strength of the alloy is at least 1,000 MPa (145 ksi) and an elongation of the alloy is at least about 10%.
 10. The titanium alloy of claim 9, wherein the UTS is at least 1100 MPa (160 ksi).
 11. The titanium alloy of claim 9, wherein the alloy has a reduction of area (RA) of at least about 25% when evaluated using an ASTM E8 standard.
 12. The titanium alloy of claim 1, wherein a V50 ballistic limit of the alloy is at least 60 feet per second (18 m/s) greater than a base V50 ballistic limit measured for a T-64 alloy when a 0.616 inch (1.56 cm) thick plate of the alloy is tested against a 12.7 mm diameter steel fragment simulating projectile.
 13. The titanium alloy of claim 1, wherein the density of the alloy is between 4.4 g/cm³ (0.161 lb./in³) and 4.55 g/cm³ (0.164 lb./in³).
 14. The titanium alloy of claim 1, wherein the alloy comprises a beta transus temperature between 1010° C. (1850° F.) and 1040° C. (1904° F.).
 15. The titanium alloy of claim 1, wherein the alloy comprises a microstructure with a primary alpha phase in a background of a beta phase and an alpha grain size of less than or equal to 15 μm.
 16. A part formed from the alloy of claim
 1. 17. A titanium alloy comprising, in weight %: aluminum from about 6.3 to 6.7; vanadium from about 1.5 to about 1.9; molybdenum from about 1.5 to about 1.9; silicon from about 0.34 to about 0.38; oxygen from about 0.18 to about 0.21; iron from about 0.1 to about 0.2; carbon from about 0.01 to about 0.05; and balance titanium with incidental impurities, wherein the alloy comprises a room temperature longitudinal low cycle fatigue (LCF) maximum stress of at least about 950 MPa over about 20,000 cycles and a room temperature transverse LCF maximum stress of at least about 970 MPa over about 25,000 cycles.
 18. The titanium alloy of claim 17, wherein the alloy consists essentially of: aluminum at about 6.5; vanadium at about 1.7; molybdenum at about 1.7; silicon at about 0.36; oxygen at about 0.2; iron at about 0.16; carbon at about 0.03; and balance titanium with incidental impurities.
 19. A titanium alloy comprising, in weight %: aluminum from about 6.3 to 6.7; vanadium from about 1.5 to about 1.9; molybdenum from about 1.5 to about 1.9; silicon from about 0.34 to about 0.38; oxygen from about 0.18 to about 0.21; iron from about 0.1 to about 0.2; carbon from about 0.01 to about 0.05; and balance titanium with incidental impurities, wherein: a molybdenum equivalence (Mo_(eq)) of the alloy is 2.6 to 4.0 and the molybdenum equivalence is defined as: Mo_(eq)=Mo+0.67V+2.9Fe; an aluminum equivalence (Al_(eq)) of the alloy is 10.6 to about 12.9 and the aluminum equivalence is defined as: Al_(eq)=Al+27O; and a room temperature longitudinal low cycle fatigue (LCF) maximum stress of the alloy is at least about 950 MPa over about 20,000.
 20. The titanium alloy of claim 19, wherein the alloy consists essentially of: aluminum at about 6.5; vanadium at about 1.7; molybdenum at about 1.7; silicon at about 0.36; oxygen at about 0.2; iron at about 0.16; carbon at about 0.03; and balance titanium with incidental impurities. 